There is provided an optical fiber cable having a plurality of optical fiber members. Each optical fiber member includes an optical fiber and a protective coating surrounding the optical fiber. A polymer coating surrounds the plurality of optical fiber members and a portion of the polymer coating is located between at least some of the optical fiber members. The optical fiber members and the polymer coating form an optical fiber unit. A tight buffer surrounds the optical fiber unit.
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15. An optical fiber cable comprising:
a plurality of optical fiber members; each optical fiber member including an optical fiber and a protective coating surrounding the optical fiber;
a polymer coating surrounding the plurality of optical fiber members forming at least one optical fiber unit; and
a thermoplastic elastomer layer surrounding the optical fiber unit forming a tight buffer; the tight buffer having an inner wall and an outer wall; the polymer coating having an outer surface; the tight buffer being extruded directly onto the outer surface of the polymer coating so that the inner wall of the tight buffer is in direct and intimate contact with the outer surface of the polymer coating; the thermoplastic elastomer material being a thermoplastic polyester elastomer or a mixture of polyethylene and ethylene propylene diene monomer.
22. An optical fiber cable comprising:
a plurality of optical fiber members; each optical fiber member including an optical fiber and a protective coating surrounding the optical fiber;
a polymer coating surrounding the plurality of optical fiber members wherein a portion of the polymer coating is located between at least some of the optical fiber members;
the optical fiber members and the polymer coating forming an optical fiber unit; and
a tight buffer surrounding the optical fiber unit; the tight buffer having an inner wall and an outer wall; the polymer coating having an outer surface; the tight buffer being extruded directly onto the outer surface of the polymer coating so that the inner wall of the tight buffer is in direct and intimate contact with the outer surface of the polymer coating; the tight buffer being primarily made from polyvinyl chloride.
21. An optical fiber cable comprising:
a plurality of optical fiber units; each optical fiber unit including a plurality of optical fiber members;
each optical fiber ember including an optical fiber and a protective coating surrounding the optical fiber;
each optical fiber unit including a polymer coating surrounding the plurality of optical fiber members wherein a portion of the polymer coating is located between at least some of the optical fiber members; and
a thermoplastic elastomer layer surrounding each of the optical fiber units forming tight buffers; each tight buffer having an inner wall and an outer wall; each polymer coating having an outer surface; each tight buffer being extruded directly onto the outer surface of each polymer coating so that the inner wall of each tight buffer is in direct and intimate contact with the outer wall of each polymer coating.
1. An optical fiber cable comprising:
a plurality of optical fiber members; each optical fiber member including an optical fiber and a protective coating surrounding the optical fiber;
a polymer coating surrounding the plurality of optical fiber members wherein a portion of the polymer coating is located between at least some of the optical fiber members;
the optical fiber members and the polymer coating forming an optical fiber unit; and
a tight buffer surrounding the optical fiber unit; the tight buffer having an inner wall and an outer wall; the polymer coating having an outer surface; the tight buffer being extruded directly onto the outer surface of the polymer coating so that the inner wall of the tight buffer is in direct and intimate contact with the outer surface of the polymer coating; the tight buffer being primarily made from a thermoplastic elastomer material.
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This is a U.S. non-provisional application relating to and claiming the benefit of U.S. Provisional Patent Application Ser. No. 61/424,275 filed Dec. 17, 2010 and U.S. Provisional Patent Application Ser. No. 61/425,578 filed Dec. 21, 2010.
Fiber optic cables are widely used in the communications industry. For indoor and outdoor applications these cables are generally provided in loose tube and tight buffer cable construction types. Loose tube cables contain one or more optical fibers within one or more loose tubes. Excess fiber length is provided within the loose tube allowing fiber movement during flexure and tensile loading. In tight buffer cables, each individual optical fiber is contained under a thermoplastic sheath applied directly to the fiber protective coating. This thermoplastic tight buffer sheath provides added protection for each fiber for crush and impact forces during handling and installation.
In addition to increased protection for crush and impact forces, tight buffer cables provide protection from moisture exposure when constructed from suitable outdoor rated materials. However, these cables contain more material than loose tubes because each fiber has an individual buffer. This additional material causes the cables to have large diameters, particularly for high fiber counts, resulting in lower fiber density and higher costs.
Loose tube cables provide high density of fibers in a compact construction, especially if the fibers are contained in ribbons. However, loose tubes have low inherent resistance to crush or impact forces and moisture exposure, so the cable must be rated for low exposure levels or protections must be provided elsewhere in the cable design. Also, fiber ribbons have a preferential bend axis which may limit the ability of the cable to perform in sharp bends without twisting.
If multiple fibers are provided in a small loose tube fiber unit design, an even more compact and higher density cable can be constructed. However, these fiber unit loose tube cables are not well suited for indoor and outdoor applications and are not designed for direct termination to multi-fiber connectors.
In accordance with one form of this invention, there is provided an optical fiber cable having a plurality of optical fiber members. Each optical fiber member includes an optical fiber and a protective coating surrounding the optical fiber. A polymer coating surrounds the plurality of optical fiber members wherein a portion of the polymer coating is located between at least some of the adjacent optical fiber members. The optical fiber members and the polymer coating form a fiber unit. A tight buffer surrounds the fiber unit. Preferably, the polymer coating is a single layer of an acrylate.
In accordance with another form of this invention, there is provided an optical fiber cable having a plurality of optical fiber members. Each optical fiber member includes an optical fiber and a protective coating surrounding the of optical fiber. A polymer coating surrounds the plurality of optical fiber members forming at least one fiber unit. A thermoplastic layer surrounds the optical fiber unit. The thermoplastic layer is in intimate contact with the polymer coating of the optical fiber unit thereby forming a tight buffer. Preferably, the tight buffer is formed by extruding thermoplastic material directly onto the fiber unit.
In one embodiment of the invention, the optical fiber cable includes a plurality of tight buffered optical fiber units.
In one embodiment, the optical fiber unit includes an aramid yarn located on the outer surface of the polymer coating which surrounds the plurality of optical fiber members. Preferably, an outer jacket is received over the tight buffered fiber unit or units.
In one embodiment, an aramid layer is formed between the outer jacket and the tight buffered fiber unit or units.
In one embodiment, there is provided a rugged fiber optic cable, which preferably is miniature, having one or more optical fiber units each containing a plurality of optical fiber members and positioned under a tight thermoplastic sheath or buffer applied directly over each optical fiber unit. Preferably, each optical fiber unit outer coating is formed using a UV cured polymer such as acrylate. The fiber optic cable may be constructed in a form suitable for installation and operation in either or both indoor and outdoor applications. Water blocking elements such as super absorbent polymer coated yarn, tapes or powders may be added for some applications.
In one embodiment, there is provided a rugged fiber optic cable, which preferably is miniature, having one or more optical fiber units each containing a plurality of optical fiber members and positioned with a strength member layer, such as aramid yarn, applied between the optical fiber unit and a tight thermoplastic sheath or buffer.
In one embodiment, there is provided a rodent deterrent fiber optic cable having one or more optical fiber units each containing a plurality of optical fiber members and constructed such that a layer of aramid yarn with optional water blocking properties is applied over the tight buffered optical fiber unit and an inner polymeric jacket is applied over the aramid yarn layer. A rodent deterrent layer, such as steel wire braid or polyester or steel tape for protection against rodents and gnawing animals, is applied over the inner polymeric jacket with an outer polymeric jacket layer applied over the steel wire layer.
As used herein “optical fiber member” means an optical fiber coated with a protective coating and “optical fiber unit” means a plurality of fiber members surrounded by a polymer coating or layer which may bind the fiber members together forming a unit. When an optical fiber unit is constructed in accordance with the teachings of this invention wherein the optical fiber unit polymer coating is in a tight or semi-tight relation with the optical fiber members and a thermoplastic tight buffer is applied directly over the optical fiber unit outer coating, a rugged outdoor rated cable can be constructed which has both high fiber density and high resistance to crush, impact, and moisture exposure. In addition, when flame retardant outdoor rated materials are used, this cable with tight buffer optical fiber unit or units can also be made suitable for both indoor and outdoor applications. For ease of stripping and termination, a release agent may be applied to both the optical fiber members within the optical fiber unit and also between the thermoplastic tight buffer and the fiber unit. Another embodiment allowing direct termination to multi-fiber connectors includes a strength member such as aramid yarn between the optical fiber unit outer coating and the thermoplastic tight buffer. This yarn may contain water blocking elements such as super absorbent polymer coatings or powders for an outdoor or indoor-outdoor design.
Referring now more particularly to
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A thermoplastic sheath 22 is applied directly over optical fiber unit outer coating 20, preferably by extrusion, so that there is substantially no space between the inside wall 24 of thermoplastic sheath 22 and the outside surface 26 of fiber unit 10. Thermoplastic sheath 22 is thus in intimate contact with outer coating 20 and therefore a tight buffer layer if formed. The thermoplastic sheath 22 may be made of various materials such as PVC or a hard elastomeric material or plastic mixtures. One preferred thermoplastic material for sheath 22, particularly for outdoor applications, is a thermoplastic polyester elastomer such as Hytrel, which is commercially available from DuPont Company. These thermoplastic elastomers are hard and perform well over a wide range of temperatures which are qualities particularly needed for outdoor applications. Other thermoplastic materials for indoor and outdoor applications may also be used, such as a thermoplastic elastomer comprising a mixture of polyethylene (“PE”) and ethylene propylene diene monomer (“EPDM”). A suitable PE/EPDM mixture is Telcar thermoplastic elastomer commercially available from Teknor Apex Company. A PE/EPDM mixture provides good bend flexibility and is flame retardant.
By using a mixture of PE and EPDM as the material for the tight buffer over the fiber unit and a non-hygroscopic thixotropic filling compound within the fiber unit, a rugged optical fiber cable may be constructed for both indoor and outdoor applications since the PE/EPDM buffer is flame retardant, which is needed for indoor applications, the non-hygroscopic thixotropic filling compound blocks water, which is needed for outdoor applications, and the PE/EPDM buffer is sufficiently tough and hard and adequately performs over a wide range of temperatures for outdoor applications. Thus, both indoor and outdoor cables may be manufactured on the same line without the need to change set up.
Tight buffer layer 22 protects the optical fiber members 14 from crushing, from mechanical shock, and from environmental exposure. Tight buffer layer 22 also eliminates the need for buffers on individual optical fiber members so that the diameter of the cable may be reduced. Preferably, the thickness of the wall of tight buffer layer is between 0.225 mm and 0.425 mm, and more preferably, the thickness is 0.325 mm.
Optical fiber unit 10 is compactly constructed as shown in
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There can also be four and twelve fiber tight buffered unarmored cables which could be identical to cables 48 and 60 shown in
The invention described herein provides for cables which have the benefits of fiber protection enabled by individual fiber unit tight buffering, yet have the high fiber density normally found in a loose tube construction. The invention provides for a rugged design which enables both indoor and outdoor design options and provides cables which have very small diameters yet the fibers are well protected from damage. In addition, by including the aramid yarn layer between the tight buffer layer and the fiber unit outer coating, one can readily terminate the cable to multi-fiber connectors such as MPO connectors.
From the foregoing description of the embodiments of the invention, it will be apparent that many modifications may be made therein. It will be understood that these embodiments of the invention are exemplifications of the invention only and that the invention is not limited thereto.
Leonard, Teddy W., Stover, Michael A., Plaski, Aaron J.
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Dec 13 2011 | STOVER, MICHAEL A | Optical Cable Corporation | ASSIGNMENT OF ASSIGNORS INTEREST SEE DOCUMENT FOR DETAILS | 027379 | /0832 | |
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